A magnetic random access memory (MRAM) stack, a method of fabricating a MRAM stack, a MRAM array, and a computer system. The MRAM stack includes a first magnetic layer comprising a Heusler compound. The MRAM stack also includes one or more seed layers including a templating structure having a crystalline structure configured to template the Heusler compound. The magnetic layer is formed over the templating structure. The MRAM stack also includes a chromium (Cr) layer formed under the templating structure. The Cr layer is configured to enhance a tunnel magnetoresistance (TMR) of the MRAM stack.
Legal claims defining the scope of protection, as filed with the USPTO.
1. A magnetic random access memory (MRAM) stack comprising: a first magnetic layer comprising a Heusler compound; and one or more seed layers comprising: a bi-layer templating structure configured to template the Heusler compound, wherein the first magnetic layer is formed over the bi-layer templating structure, the bi-layer templating structure formed from a first layer comprising a first binary alloy having a cesium-chloride (CsCl) structure as represented by A1-xEx, and a second layer comprising a second binary alloy having the cesium-chloride (CsCl) structure as represented by A1-xEx, wherein A is a transition metal element and E is a main group element, and wherein the first binary alloy comprises a different transition metal than the second binary alloy; and a chromium (Cr) layer formed under the bi-layer templating structure, the Cr layer is configured to enhance a tunnel magnetoresistance (TMR) of the MRAM stack.
2. The MRAM stack of claim 1 further comprising: a second magnetic layer; and a tunnel barrier positioned between, and in contact with, one or more of the first magnetic layer and the second magnetic layer, wherein: the first magnetic layer comprises a storage layer; the second magnetic layer comprises a reference layer; and the first magnetic layer, the tunnel barrier, and the second magnetic layer define a magnetic tunnel junction (MTJ).
3. The MRAM stack of claim 2, wherein: the tunnel barrier is formed from compounds selected from the group consisting of MgO and Mg1-zAl2+(2/3)zO4, wherein −0.5<z<0.5.
4. The MRAM stack of claim 1 further comprising: a second magnetic layer; and a tunnel barrier positioned between, and in contact with, one or more of the first magnetic layer and the second magnetic layer, wherein: the second magnetic layer comprises a storage layer; the first magnetic layer comprises a reference layer; and the first magnetic layer, the tunnel barrier, and the second magnetic layer define a magnetic tunnel junction (MTJ).
5. The MRAM stack of claim 1, wherein the first magnetic layer has magnetization which is predominantly orientated perpendicular to the thickness of the film and a thickness less than 5 nanometers (nm).
6. The MRAM stack of claim 1, wherein the first magnetic layer is formed from compounds of Mn3Z, wherein: Z is an element selected from the group consisting of germanium (Ge), tin (Sn), and antimony (Sb); and the compounds of Mn3Z are selected from the group consisting of Mn3.3-xGe, Mn3.3-xSn, and Mn3.3-xSb, x in a range from 0 to 1.1.
7. The MRAM stack of claim 1, wherein the Heusler compound is a ternary Heusler compound selected from the manganese-cobalt-tin group consisting of Mn3.3-xCo1.1-ySn, in which x≤1.2 and y≤1.0.
8. The MRAM stack of claim 1, wherein the Heusler compound is chosen from the group consisting of Mn3Al, Mn3Ga, Mn3In, Mn2FeSb, Mn2CoAl, Mn2CoGe, Mn2CoSi, Mn2CuSi, Mn2CoSn, Co2CrAl, Co2CrSi, Co2MnSb, and Co2MnSi.
9. The MRAM stack of claim 1, wherein the Heusler compound is Mn3Ge.
10. The MRAM stack of claim 1, wherein a value of the variable x of the cesium-chloride (CsCl) structure as represented by A1-xEx ranges from 0.45 to 0.55.
11. The MRAM stack of claim 10, wherein: the first binary alloy of the first layer of the bi-layer templating structure comprises cobalt-aluminum (CoAl) and the second binary alloy of the second layer of the bi-layer templating structure comprises iridium-aluminum (IrAl); and the bi-layer templating structure and the Cr layer define a crystalline structure templating tri-layer.
12. A method of fabricating a magnetic random access memory (MRAM) stack comprising: forming one or more seed layers comprising: forming a chromium (Cr) layer above a substrate; forming a bi-layer templating structure over the Cr layer, the bi-layer templating structure formed from a first layer comprising a first binary alloy having a cesium-chloride (CsCl) structure as represented by A1-xEx, and a second layer comprising a second binary alloy having the cesium-chloride (CsCl) structure as represented by A1-xEx, wherein A is a transition metal element and E is a main group element, and wherein the first binary alloy comprises a different transition metal than the second binary alloy; and forming a first magnetic layer comprising: templating a Heusler compound through the templating structure, wherein: the Cr layer is configured to enhance a tunnel magnetoresistance (TMR) of the MRAM stack.
13. The method of claim 12, further comprising: templating the Heusler compound over the templating structure.
14. The method of claim 12, further comprising: forming a tunnel barrier over the first magnetic layer; forming a second magnetic layer over the tunnel barrier, thereby positioning the tunnel barrier between, and in contact with, the first magnetic layer and the second magnetic layer, wherein: the first magnetic layer defines a storage layer; the second magnetic layer define a reference layer; and the first magnetic layer, the tunnel barrier, and the second magnetic layer define a magnetic tunnel junction (MTJ).
15. The method of claim 12, further comprising: forming a tunnel barrier over the first magnetic layer; forming a second magnetic layer over the tunnel barrier, thereby positioning the tunnel barrier between, and in contact with, the first magnetic layer and the second magnetic layer, wherein: the second magnetic layer defines a storage layer; the first magnetic layer define a reference layer; and the first magnetic layer, the tunnel barrier, and the second magnetic layer define a magnetic tunnel junction (MTJ).
16. The method of claim 12, wherein a value of the variable x of the cesium-chloride (CsCl) structure as represented by A1-xEx ranges from 0.45 to 0.55.
17. The method of claim 12, wherein the templating the Heusler compound through the bi-layer templating structure comprises one or more of: templating the first magnetic layer from compounds of Mn3Z, wherein: Z is an element selected from the group consisting of germanium (Ge), tin (Sn), and antimony (Sb); and templating the first magnetic layer where the compounds of Mn3Z are selected from the group consisting of Mn3.3-xGe, Mn3.3-xSn, and Mn3.3-xSb, x in a range from 0 to 1.1.
18. The method of claim 13, wherein the templating the Heusler compound through the bi-layer templating structure comprises one or more of: templating the first magnetic layer from a ternary Heusler compound selected from the manganese-cobalt-tin group consisting of Mn3.3-xCo1.1-ySn, in which x≤1.2 and y≤1.0; templating the first magnetic layer from the Heusler compound chosen from the group consisting of Mn3Al, Mn3Ga, Mn3In, Mn2FeSb, Mn2CoAl, Mn2CoGe, Mn2CoSi, Mn2CuSi, Mn2CoSn, Co2CrAl, Co2CrSi, Co2MnSb, and Co2MnSi; and templating the first magnetic layer from the Heusler compound of Mn3Ge.
19. A magnetic random-access memory (MRAM) array, comprising: a plurality of bit lines and a plurality of corresponding complementary bit lines forming a plurality of bit line-complementary bit line pairs; a plurality of word lines intersecting the plurality of bit line pairs at a plurality of cell locations; a plurality of MRAM cells located at each cell location of the plurality of cell locations, each MRAM cell of the plurality of MRAM cells being electrically connected to a corresponding bit line of the plurality of bit lines and selectively interconnected to a corresponding one of the plurality of the complementary bit lines under control of a corresponding one of the word lines of the plurality of word lines, each MRAM cell of the plurality of MRAM cells comprising: a first magnetic layer comprising a Heusler compound; and one or more seed layers comprising: a bi-layer templating structure configured to template the Heusler compound, wherein the first magnetic layer is formed over the bi-layer templating structure, the bi-layer templating structure formed from a first layer comprising a first binary alloy having a cesium-chloride (CsCl) structure as represented by A1-xEx, and a second layer comprising a second binary alloy having the cesium-chloride (CsCl) structure as represented by A1-xEx, wherein A is a transition metal element and E is a main group element, and wherein the first binary alloy comprises a different transition metal than the second binary alloy; and a chromium (Cr) layer formed under the templating structure, the Cr layer is configured to enhance a tunnel magnetoresistance (TMR) of each MRAM cell of the plurality of MRAM cells.
20. The MRAM array of claim 19 further comprising: a second magnetic layer; and a tunnel barrier positioned between, and in contact with, one or more of the first magnetic layer and the second magnetic layer, wherein: the first magnetic layer comprises one of a storage layer and a reference layer; the second magnetic layer comprises one of a reference layer and a storage layer in opposition to the first magnetic layer; and the first magnetic layer, the tunnel barrier, and the second magnetic layer define a magnetic tunnel junction (MTJ).
21. The MRAM array of claim 19, wherein: each word line of the plurality of word lines is configured to receive one or more signals to cause a first subset of the plurality of MRAM cells to store logical ones and a second subset of the plurality of MRAM cells to store logical zeroes; and each bit line-complementary bit line pair of the plurality of bit line-complementary bit line pairs is configured to read the stored logical ones and zeroes.
22. A computer system comprising: one or more processing devices; one or more memory devices communicatively and operably coupled to the one or more processing devices, at least one memory device of the one or more memory devices comprising one or more magnetic random access memory (MRAM) devices, each MRAM device of the one or more MRAM devices comprising: a first magnetic layer comprising a Heusler compound; and one or more seed layers comprising: a bi-layer templating structure configured to template the Heusler compound, wherein the first magnetic layer is formed over the bi-layer templating structure, the bi-layer templating structure formed from a first layer comprising a first binary alloy having a cesium-chloride (CsCl) structure as represented by A1-xEx, and a second layer comprising a second binary alloy having the cesium-chloride (CsCl) structure as represented by A1-xEx, wherein A is a transition metal element and E is a main group element, and wherein the first binary alloy comprises a different transition metal than the second binary alloy; and a chromium (Cr) layer formed under the templating structure, the Cr layer is configured to enhance a tunnel magnetoresistance (TMR) of each MRAM device of the one or more MRAM devices.
23. The computer system of claim 22 further comprising: a second magnetic layer; and a tunnel barrier positioned between, and in contact with, one or more of the first magnetic layer and the second magnetic layer, wherein: the first magnetic layer comprises one of a storage layer and a reference layer; the second magnetic layer comprises one of a reference layer and a storage layer in opposition to the first magnetic layer; and the first magnetic layer, the tunnel barrier, and the second magnetic layer define a magnetic tunnel junction (MTJ).
24. The computer system of claim 22, wherein: the first binary alloy of the first layer of the bi-layer templating structure comprises cobalt-aluminum (CoAl) and the second binary alloy of the second layer of the bi-layer templating structure comprises iridium-aluminum (IrAl); and the bi-layer templating structure and the Cr layer define a crystalline structure templating tri-layer.
25. The method of claim 16, wherein: the first binary alloy of the first layer of the bi-layer templating structure comprises cobalt-aluminum (CoAl) and the second binary alloy of the second layer of the bi-layer templating structure comprises iridium-aluminum (IrAl); and the bi-layer templating structure and the Cr layer define a crystalline structure templating tri-layer.
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June 17, 2022
April 8, 2025
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